Method of forming edgewise wound cores

ABSTRACT

A method of continuously forming edgewise wound cores from a strip of generally thin ferromagnetic material at at least one operation station therefor having a means for receiving the cores. The receiving means includes a pair of separable means adapted for association with each other and separation, and a set of supporting means is operable generally in one of the separable means for movement between retracted and protracted positions, respectively. In the practice of this method, the continuous strip is deformed generally edgewise thereof into a plurality of helical convolutions at the at least one operation station. The separable means are separated from each other, and thereby the operation of the supporting means toward the protracted positions thereof is effected. A part of each supporting means is extended beyond the one separation means when the supporting means are in the protracted positions thereof, and at least some of the helical convolutions are received generally in an axial stack thereof about the one separable means on the supporting means parts when the supporting means are in the protracted positions thereof, respectively.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a division of parent application Ser. No. 660,116 filed Oct. 12, 1984 (now U.S. Pat. No. 4,643,012 issued Feb. 17, 1987) and is related to the following listed, commonly assigned, applications filed concurrently with such parent application, and such parent application and related applications are incorporated by reference herein, respectively:

(1) Application Ser. No. 660,101 filed Oct. 12, 1984 of James L. King entitled "Lanced Strip, Dynamoelectric Machine, Core, Method Of Forming Such Core, Stationary Assembly, And Method Of Assembling Such Stationary Assembly"; and

(2) Application Ser. No. 660,211 filed Oct. 12, 1984 (now U.S. Pat. No. 4,613,780 issued Sept. 23, 1986) of Harold L. Fritzsche entitled "Lanced Strip, Core, Method Of Forming Such Core, And Apparatus", (now U.S. Pat. No. 4,613,780 issued Sept. 23, 1986).

FIELD OF THE INVENTION

This invention relates in general to dynamoelectric machines and in particular to methods for forming edgewise wound cores adapted for use in such dynamoelectric machine.

BACKGROUND OF THE INVENTION

In the past, various and sundry apparatus and methods have been utilized for forming edgewise wound cores adapted for use in dynamoelectric machines. For instance, in some of the past apparatus and methods for forming edgewise wound cores, a continuous strip of a generally thin ferromagnetic material was deformed or bent generally edgewise thereof into a plurality of helical convolutions. Of course, various different techniques were employed to effect the edgewise deformation of the continuous strip into the helical convolutions thereof. Subsequent to the edgewise deformation of the continuous strip into the helical convolutions thereof, such helical convolutions were collected or wound about a winding arbor therefor so as to form a generally axial stack of the helical convolutions. When the generally axial stack of helical convolutions so collected attained a preselected stack height or length to define the edgewise wound core being formed, the operation of some of the past apparatus for forming such cores was interrupted to permit severance of a respective one of the helical convolutions and the removal of the edgewise wound core from the winding arbor. In some cases an operator manually removed the edgewise wound cores from the winding arbor on which they were formed, and in other instances, a stripper or pusher was automatically operable to move the formed edgewise wound core from the winding arbor onto another aligned arbor. Of course, the above described intermittent operation of some past apparatus was repetitive thereby to intermittently effect the formation of a plurality of edgewise wound cores from the continuous strip. At least one of the disadvantageous or undesirable features of the above discussed past apparatus is believed to be that the intermittent operation thereof may have resulted in an unnecessarily limited production capacity.

In another of the past apparatus and methods of forming edgewise wound cores, the operation of such apparatus was continuous thereby to effect a continuous edgewise deformation of the continuous strip into a plurality of helical convolutions thereof, and the continuous helical convolutions were collected or wound generally in an axial stack thereof about the winding arbor generally in the same manner as discussed hereinabove with respect to the past intermittently operable apparatus. When a preselected length of the continuously formed helical convolutions had been collected in the axial stack on the winding arbor so as to define an edgewise wound core, a respective one of the helical convolutions was severed. The formed edgewise wound core was stripped either by hand or automatically from the winding arbor on which it was wound to another aligned stripping arbor, and during such stripping, a successive one of the edgewise wound cores was being wound from the continuous helical convolutions received on the winding arbor therefor. While this type of continuously operable apparatus undoubtedly exhibited many salient features, at least one of the disadvantageous or undesirable features of such apparatus is believed to be that it was operable only in a generally horizontal plane. Another disadvantageous or undesirable feature of such apparatus is believed to be that the entire axial stack of helical convolutions were formed into an edgewise wound core on the winding arbor therefor and then moved to a stripping arbor with each arbor having a length to accept such edgewise wound core may have resulted in an overly long or cumbersome arbor combination. Still another disadvantageous or undesirable feature is believed to be that a separate stripping device was employed to strip the edgewise wound core from the winding arbor into the stripping arbor with yet other means being employed to effect the stripping or removal of the edgewise wound core from the stripping arbor.

SUMMARY

Among the several objects of the present invention may be noted the provision of improved methods for continuously forming edgewise wound cores which overcome, at least in part, the disadvantageous or undesirable features discussed above, as well as others, with respect to the prior art; the provision of such improved methods wherein at least some continuously deformed helical convolutions are accumulated into a part of successive ones of the edgewise wound cores at an operation station of an apparatus for continuously forming the edgewise wound cores while respective ones of the edgewise wound cores already formed at such operation station are translated to another operation station of the apparatus; the provision of such improved methods wherein the continuously deformed convolutions forming such edgewise wound core parts are accumulated on one separable means of a pair thereof adapted for receiving the helical convolutions while the other of the separable means is operable to effect the translation of such already formed respective ones of the edgewise wound cores to the another work station of the apparatus; the provision of such improved methods wherein such edgewise wound core parts are automatically transferred from the one separable means to the other separable means upon the association of the separable means with each other; the provision of such improved methods wherein the other separable means comprises a stripping arbor on which the edgewise wound cores are formed; the provision of such improved methods wherein such edgewise wound core parts are received on the one separable means at the one operation station of the apparatus without interrupting the delivery of the continuously deformed helical convolutions upon the operation of the stripping arbor to translate such already formed edgewise wound cores to the another work station of the apparatus; the provision of such improved methods in which means are operable in one position with respect to the one separable means for supporting such edgewise wound core parts and operable in another position with respect to the one separable means for effecting the transfer of the edgewise wound core parts from the one separable means to the stripping arbor; and the provision of such improved methods in which the components utilized therein are simple in design, economically manufactured and easily assembled. These as well as other objects and advantageous features of the present invention will be in part apparent and in part pointed out hereinafter.

In general and in one form of the invention, a method is provided for continuously forming edgewise wound cores at at least one operation station from a continuous strip of a generally thin ferromagnetic material with the at least one operation station having a means for receiving the edgewise wound cores including a pair of means associated with each other and adapted for separation. In this method, the continuous strip is formed into one of the edgewise wound cores generally about the receiving means thereofr at the at least one winding staiton, and the one edgewise wound coreis supported at least during the formation thereof on one of the separation means of the receiving means. The one edgewise wound core is severed upon the formation thereof from the continuous strip, and the one separation means with the one edge wise wound core supported therein is separated from the otehr of the separation means. The formation of the continuous strip into at least a part of another of the edgewise wound cores is continued generally about the other separation means of the receiving means, and the at least part of the another edgewise wound core is supported on the other separation means at least during the separation therefrom of the one separation means.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side elevational view showing apparatus for continuously forming edgewise wound cores and illustrating principles which may be practiced in methods for continuously forming edgewise wound cores in one form of the invention;

FIG. 1A is a schematic diagram showing a winder speed control of the apparatus and a circuit therefor including certain sensors also shown in FIG. 1;

FIG. 2 is a partial plan view illustrating lancing steps involved in dividing of strip stock of a ferromagnetic material at an operating station of the apparatus into two continuous strips each having a preselected configuration;

FIG. 3 is a partial schematic view and a partial sectional view illustrating certain details of the apparatus of FIG. 1 for punching out portions of the strip stock to divide it into the two continuous strips including means for sensing strip thickness and also showing diagrammatically an electric and a pneumatic circuit controlled by the sensing means;

FIG. 4 is an enlarged partial side elevational view of the apparatus taken from FIG. 1 illustrating winding means of the apparatus with parts thereof being broken away for clarity;

FIG. 5 is a partial plan view of the apparatus taken from FIG. 4 with parts broken away for clarity;

FIG. 6 is a diagrammatic view illustrating the paths of travel of the two strips to the respective winding means therefor and the directions of winding of the continuous strips;

FIG. 7 is a sectional view taken along line 7--7 of FIG. 5;

FIG. 8 is a sectional view taken along line 8--8 of FIG. 7;

FIG. 9 is an enlarged fragmentary view taken from FIG. 7;

FIG. 10 is a partial sectional view taken along line 10--10 of FIG. 5 with parts broken away for clarity;

FIG. 11 is an enlarged fragmentary view of FIG. 5 with parts broken away for clarity;

FIG. 12 is a plan view of a strip guide per se of the apparatus of FIG. 1;

FIG. 13 is an enlarged partial sectional view taken along line 13--13 of FIG. 11;

FIG. 14 is an enlarged partial sectional view taken along line 14--14 of FIG. 7;

FIG. l5 is an enlarged partial sectional view taken along line 15--15 of FIG. 5 with parts broken away for clarity;

FIG. 16 is an enlarged fragmentary view taken from FIG. 15 with parts broken away and shown in section;

FIG. 17 is an end view of an edgewise wound core formed in accordance with this invention for use in a dynamoelectric machine in a typical as-wound state of the core with teeth and slots of adjacent helical convolutions of the core angularly displaced;

FIG. 18 is a side elevational view of the edgewise wound core of FIG. 17;

FIG. 19 is a plan view similar to FIG. 17 but showing the edgewise wound core after an operation to align the teeth and slots of the helical convolutions thereof;

FIG. 20 is a side elevational view of the edgewise wound core of FIG. 19;

FIG. 21 is a partial plan view similar to FIG. 5 showing an alternative apparatus for continuously forming edgewise wound cores and illustrating principles which may be practiced in an alternative method for continuously forming edgewise wound cores in one form of the invention;

FIG. 22 is a partial elevational view of the alternative apparatus of FIG. 21 illustrating separate winding means thereof; and

FIG. 23 is a schematic diagram showing separate speed controls for the separate winding means of the alternative apparatus and a circuit therefor including certain sensors illustrated in FIG. 22.

Corresponding reference characters indicate corresponding parts throughout several views of the drawings.

The exemplifications set out herein illustrate the preferred embodiments of the invention in one form thereof, and such exemplifications are not to be construed as limiting either scope of the invention or the scope of the disclosure thereof in any manner.

DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring to the drawings and in particular to FIG. 1, there is shown apparatus having an operation or work station indicated generally at 1 at which a metal strip stock 3 is operated upon to divide or lance it into a plurality of individual strips having preselected configurations, each for being edgewise wound into helices defining edgewise wound cores. In particular, strip stock 3 is a generally thin strip of ferromagnetic material suitable for making cores for dynamoelectric machines, such as for instance stator or rotor cores for electric motors. As herein illustrated, strip stock 3 is divided or lanced into a plurality of continuous strips, such as a pair thereof as designated 5A, 5B (see FIGS. 2, 5 and 6). These continuous strips are identical, each comprising what may be termed a continuous band 7 extending longitudinally or lengthwise with respect to the strip and a series of teeth 9 extending generally laterally outwardly from the band at one side thereof with a series of slots 11 between adjacent ones of the teeth. Teeth 9 of each strip comprise material taken from the regions of slots 11 of the adjacent strip for reduction of waste of the ferromagnetic material, and the teeth extend into the slots of the adjacent strip. As herein illustrated, each strip is edgewise wound into a stator core C (see FIGS. 4, 7, 9 and 17-20) for an electric motor with band 7 of the strip forming the yoke or yoke section of the core and teeth 9 extending radially inwardly from the yoke. In the core, in its completed state as illustrated in FIGS. 19 and 20, teeth 9 of adjacent helical convolutions of the strip are aligned, as are slots 11, so that the core has coil slots at 11 for receiving windings (not shown).

At 13 in FIG. 1 is indicated a supply (a coil) of strip stock 3 which is intermittently fed in increments from this supply to operating station 1 of the apparatus with a dwell between successive feed cycles. At operation station 1, strip stock 3 is operated upon to divide it into continuous strips 5A, 5B which are intermittently fed from the operation station concomitantly with the feed of the strip stock thereto, and the continuous strips are separated one from the other thereafter passing to a plurality of other respective operation or work stations, such as for instance a pair of winding stations indicated generally at 15A, 15B. Each of strips 5A, 5B is continuously wound generally edgewise thereof into a helix at the respective winding station, as will be discussed in detail hereinafter.

In accordance with an aspect of this invention, a looped portion of strips 5A, 5B is provided, as indicated at 17 in FIGS. 1, 1A and 4, between operation station 1 and winding stations 15A, 15B. Looped portion 17 is such as to enable continuous feed of continuous strips 5A, 5B from the looped portion to winding stations 15A, 15B during each dwell of strip stock 3 between successive intermittent feed cycles (when the strip stock and the initial portion of the continuous strips just upstream from and leading into the looped portion are stationary) and also during such feed cycles (when the strip stock and said portion of the continuous strips are moving) for the continuous winding of the continuous strips. Thus, looped portion 17 enables transition from the intermittent feed of strip stock 3 to the continuous feed of strips 5A, 5B to winding stations 15A, 15B. As will appear, the rate at which each strip 5A, 5B is wound at winding stations 15A, 15B relative to the rate at which it is fed from operation station 1 into looped portion 17 is varied upon increase or decrease in the size of the looped portion to maintain the looped portion of each strip for transition from the intermittent feed thereof from the operation station into the looped portion to the continuous feed of the strip out of the looped portion to the respective winding station. As shown in FIG. 1 and also in FIG. 1A, strips 5A, 5B are looped at 17 before they separate for being wound.

The division of strip stock 3 at operation station 1 into strips 5A, 5B with their teeth 9 and slots 11 is effected by a means for lancing the strips, such as a punch press generally designed 19 or the like for instance, which is shown in FIG. 1 as comprising a bed 21 mounted in a frame 23 standing on floor F. This may be a standard commercially available press such as a PULSAR press sold by Minster Press Co. of Minster, Ohio. Press 19 includes a die 25 mounted on bed 21 of the press, and the die has a set of openings indicated in its entirety at 27 in FIG. 2 for receiving a set of punches 29 (see FIGS. 1 and 2) to punch out portions of strip stock 3 on each cycle of the press to lance or effect the division of the stock into strips 5A, 5B with the formation of teeth 9 and slots 11 thereof. Punches 29 are carried by vertically reciprocable press head 31 which is driven upwardly and downwardly through return and punch strokes by conventional press mechanism indicated schematically by a dotted line at 33 in FIG. 1 and driven by a continuously rotating press shaft or continuous driving means 35. A stripper or pressure plate 37 (see FIG. 3) carried by press head 31 is backed by springs 39 to apply pressure to strip stock 3 on die 25 as press head 31 comes down. Strip stock 3 is intermittently fed over die 25 in increments appropriate to die openings 27 for forming teeth 9 and slots 11 for each of strips 5A, 5B, and this feed is effected by feeding means, such as a pair of intermittently operable stock feed rolls or the like for instance as indicated at 41 in FIG. 1, intermittently driven from press shaft 35 by a conventional mechanism as indicated schematically by a dotted line at 43 in FIG. 1.

As illustrated in FIG. 2, die 25 is in effect divided into a series of six die zones D1-D6 extending in the direction of the feed of strip stock 3 over the die, and each of these zones has a length corresponding generally to six times the spacing or pitch of teeth 9 of one strip (twelve times the spacing of adjacent teeth); however, it is contemplated that other such zones having different lengths corresponding to different pitch for the teeth may be utilized within the scope of the invention so as to meet at least some of the objects thereof. Feed rolls 41 act intermittently to feed over die 25 a length of strip stock 3 referred to as the index length corresponding to the zone length or six times the pitch of the teeth, with a dwell of the strip stock feed occurring between successive feed cycles thereof. With reference to the index length corresponding to six times the pitch of the teeth, it is to be noted that the invention is herein illustrated as it relates to the formation of the cores C with twenty-four teeth 9 and twenty-four slots 11; however, it is contemplated that other cores having various other configurations and different numbers of teeth and slots may be formed within the scope of the invention so as to meet at least some of the objects thereof. Each helical convolution of a core C thus has twenty-four teeth and twenty-four slots which are generated on four successive indexing steps. Punches 29 are, of course, raised during the dwell to accommodate the feed of strip stock 3. In the first zone D1, field pins 44 punch holes 45 in strip stock 3. In the second zone D2, die 25 has an arrangement of lenticular openings therein, such as indicated at 46, and press head 31 has a corresponding arrangement of punches 47 for punching lenticular openings 49 in strip stock 3 in two rows thereby to form concave inner ends for slots 11 and generally straight inner ends for the tips of teeth 9. In third and fourth zones D3, D4, die 25 has an arrangement of openings 51, and press head 31 has a corresponding arrangement of punches 53 for punching out portions of strip stock 3 to form scallops 55 at the outer edges of the strips extending between outwardly projecting tongues or lands 57. In fourth and fifth zones D4, D5, die 25 has an arrangement of openings 59, and press head 31 has a corresponding arrangement of punches 61 for punching narrow transverse slots 63 in strip stock 3 extending between pairs of lenticular openings 49 to form first spaces at 63 between teeth 9. And in the fifth and sixth zones D5, D6, die 25 has an arrangement of openings 65, and press head 31 has a corresponding arrangement of punches 67 for punching narrow transverse slots 69 in strip stock 3 extending between the aforementioned paired lenticular openings 49 to form second spaces at 69 between teeth thereby to complete the division or lancing of strip stock 3 into continuous strips 5A, 5B, as illustrated at the bottom of FIG. 2. Punches 29 all come down simultaneously in the above discussed several zones with press head 31 and are then raised to open press 19 for the feed of the stock one index length. The operation is such that the formation of teeth 9 and slots 11 takes place in steps as strip stock 3 is indexed through the successive zones, and the strip stock is ultimately completely lanced into strips 5A, 5B each with its teeth 9 and slots 11 in zones D5, D6. Although press 19 is illustrated herein to effect the lancing of strips 5A, 5B from stock 3, it is contemplated that various other lancing means or presses may be utilized to lance either one strip of the stock into the desired configuration thereof or to lance a plurality of the strips from the stock within the scope of the invention so as to meet at least some of the objects thereof.

Associated with die 25 and stripper or pressure plate 37 is means indicated generally at 71 in FIG. 3 for measuring the thickness of strip stock 3 on the die since the thickness may vary from section-to-section lengthwise thereof and from roll-to-roll of stock 3 from which the strips are lanced. Measuring means 71 comprises an eddy current type of sensor 73, such as for instance a KD-2611-28 sensor available from Kaman Sciences Corporation of Colorado Springs, Colo., set in an opening 75 at the top of die 25, in vertical alignment with an aluminum insert 76 in plate 37 which is made of steel. Sensing means or sensor 73 is laterally offset from the strip material. When press head 31 is driven downwardly through a working stroke and plate 37 comes into spring-pressured engagement with the top of strip stock 3 on die 25 thereby to press it onto the upper face of the die, sensor 73 generates an electrical signal related to the height of the gap between the upper face of the die and the lower face of the plate and hence related to the thickness of strip stock 3. The purpose of this is to control the thickness in axial direction of edgewise wound cores C, this thickness being determinative of the stack height of the edgewise wound cores formed on the apparatus, all as will appear.

Strips 5A, 5B are formed by the above discussed punching or lancing operation feed from zone D6 at the exit end of die 25 in coplanar interdigitated relation in a generally horizontal plane at the top of the die concomitantly with the feed thereto of strip stock 3 by feed rolls 41. Strips 5A, 5B advance intermittently from die 25 one index length on each feed cycle, and upon passing from the die, the strips deflect upwardly into looped portion 17, which is a single free loop including both strips and which is maintained for transition from the intermittent feed of strip stock 3 through press 19 to the continuous feed of the strips to winding stations 15A, 15B. Coming out of looped portion 17, strips 5A, 5B are vertically separated, the teeth of each strip being vertically displaced from the slots of the other, and the strips then travel in offset paths, as best seen at the upper right of FIG. 4, to winding stations 15A, 15B with strip 5B traveling above strip 5A. Each strip remains generally in the same plane in which it was generated in press 19 so as to at least limit twisting and lateral deflection of the strips passing to winding stations 15, 15A and thereby avoid stresses and strains which might deleteriously affect the magnetic characteristics of the material.

Strips 5A, 5B are continuously edgewise wound into helices or a plurality of helical convolutions (i.e., formed into edgewise wound cores C) by a plurality of winding or deforming means, such as for instance a pair of winders 77A, 77B at winding stations 15A, 15B. In each case, the strip is wound with band 7 on the outside, forming the yokes of the cores being made, and with teeth 9 extending radially inwardly. Winders 77A, 77B are mounted in a frame structure generally designated 79 which includes an upper horizontal plate 81 and a lower horizontal plate 83 supported on press 19 generally at its exit side. Winder 77A comprises rotatable means which includes a tubular spindle 85 (see FIG. 7) journaled for rotation on a vertical axis in bearings 87 in a tubular bearing block 89 mounted on upper frame plate 81 and extending upwardly therefrom, and the spindle has a circular flange 93 adjacent its lower end below the upper frame plate. An annular head or ring 95 is secured to flange 93 adjacent the lower end thereof for rotation with spindle 85 on the spindle axis. This head or ring has a flat horizontal annular bottom or gripping surface 97 and is in the nature of a flywheel acting as a friction drive wheel or gripping means for gripping engagement with an opposite face of strip 5A as will appear. At 99 is indicated a mandrel around which strip 5A is bent generally edgewise thereof to form it into a helix as will appear. Mandrel 99 is rotatable with spindle 85 on the spindle axis and is adjustable upwardly and downwardly relative to the spindle. An upper cylindric section 101 (see FIG. 9) on mandrel 99 is slidable vertically in a central opening 103 of drive wheel 95, and a lower section 103 of the mandrel is of varying diameter. More particularly, lower section 103 is of a frusto-conical form having a conic surface convergent generally in a downward direction from upper cylindric section 101. Mandrel 99 is secured by a cross-pin 105 to an enlarged lower end 107 of a mandrel adjusting stem 109 which is vertically slidable in tubular spindle 85. Enlargement 107 itself is slidable in an enlarged lower end extension 111 of spindle 85 which has a plurality of vertical slots 113 receiving cross-pin 105 for keying the mandrel to spindle 85. Spindle 85 has a gear 115 adjacent its upper end which is driven through a drive train indicated generally at 117 (see FIGS. 1 and 5), to be more particularly described.

Friction drive wheel 95 at the lower end of spindle 85 comprises a part of means for drawing strip 5A through at least a part of winder 77A defined by a bending or deforming zone indicated at B in FIGS. 11 and 12 in which the strip is constrained to bend edgewise around an axis A of the bending zone which corresponds to that of spindle 85, head 95 and mandrel 99 (the winding axis) for generally edgewise deforming the strip into a helix. This strip drawing means, in addition to wheel 95, comprises other rotatable means, such as a rotary presser wheel 119 or the like for instance, which may also be referred to as the pinch wheel having a surface or gripping means biased by a spring or spring means 121 (see FIG. 10) to press against an opposite face of strip 5A in gripping engagement therewith, more particularly against band portion 7 of the strip, so as to engage the strip generally flatwise as it travels beyond bending zone B against bottom face 97 of drive wheel 95 rotating on axis A. Pinch wheel 119 is keyed to a shaft 123 for rotation therewith and is axially slidable on the shaft, and the compressive force of spring 121 as disposed about pin 125 threaded in the end of the shaft is exerted upwardly against the pinch wheel from a head 127 on the pin. Shaft 123 is journalled in a vertical bearing 128, and pinch wheel 119 is positively driven along with the spindle 85, drive wheel 95 and mandrel 99 via a drive train as will appear. Pinch wheel 119 has a rim 129 lapping bottom face 97 of friction drive wheel 95 over the area indicated at 130 in FIG. 11, which may be referred to as a pressing or gripping zone.

As strip 5A is drawn through bending zone B, it is constrained to bend edgewise around mandrel 99 by a strip guide or deforming means 131 (see especially FIGS. 7, 9, 12 and 13), which may also be referred to as a deforming or bending guide or tool, comprising an elongate metal block having a flange 133 forming a recess 135 in one side thereof. A bending surface or edge 137 of guide 131 in recess 135 thereof is engageable by an opposite edge of strip 5A which is illustrated herein for purposes of disclosure as being on lands 57 of the strip, and the bending edge is shaped to bend the strip generally edgewise thereof generally into a circle or helical convolution around mandrel 99. This bending occurs in a horizontal plane P (see FIGS. 7 and 13), which may be referred to as the bending or winding plane, immediately adjacent and below bottom face 97 of friction drive wheel 95. For this purpose, bending edge 137 is straight for an initial or entrance portion of its length, as indicated at 137a in FIG. 12, and then becomes curved or arcuate for a portion of its length, as indicated at 137b, the curvature being such as to effect the aforementioned requisite edgewise bending of the strip. In general, the radius of curvature of portion 137b of bending edge 137 at its exit end corresponds to the desired external radius for a finished edgewise wound core.

Bending guide or tool 131 is adjustable horizontally in and out relative to mandrel 99 and, in addition to being so adjustable, is spring-biased upwardly to effect spring-pressure engagement, as indicated at 139 in FIG. 13, of the inside face of its flange 133 with strip 5A, and more particularly with band portion 7 of the strip thereby to confine the strip generally flatwise between the inside face of the flange and the bottom face of wheel 95 and restrain the strip from buckling. For this purpose, bending guide 131 is carried by a slide 141 which is horizontally slidable toward and away from mandrel 99 on a pair of horizontal guide rods 143 mounted in an opening 145 in upper plate 81. Bending guide 131 is also mounted for vertical movement relative to slide 141 by means of a pair of pins 147 extending slidably in holes 149 in the slide, the bending guide being biased upwardly toward wheel 95 by means of springs 151 surrounding pins 147 and exerting their compressive forces upwardly from the slide against heads 153 on the pins.

Means indicated generally at 155 (see FIG. 7) is provided for adjusting mandrel 99 axially upwardly and downwardly to present different winding diameters on the conic surface of lower section 103 of the mandrel in winding plane P and for adjusting bending guide 131 horizontally toward and away from the mandrel to compensate for such vertical adjustment of the mandrel diameter in the winding plane P, i.e., to maintain the proper spacing of bending edge 137 on the bending guide from the mandrel for the effective width of strip 5A between the opposite edges thereof. These adjustments may be made to accommodate spring-back of the helical convolutions of the strip so that edgewise wound cores C may be made to a preselected final diameter, as will be explained hereinafter. Since lower section 103 of mandrel 99 is of frusto-conical form as illustrated, the winding diameter of the mandrel in winding plane P is increased on downward adjustment of the mandrel and increased on upward adjustment thereof. Bending guide 131 is adjusted outwardly on increase in the effective mandrel diameter and inwardly on the decrease thereof. Although conic surface on lower section 103 of mandrel 99 is shown and described herein for purposes of disclosure, it is understood that a generally cylindric surface may be employed in place of such conic surface within the scope of the invention so as to meet at least some of the objects thereof, and in the event such cylindric surface is employed, then the adjustment of the mandrel would become moot. As appears to advantage in FIG. 7, adjusting means 155 comprises an adjustment carriage 157 mounted for vertical adjustment movement relative to a bracket 159 carried by bearing block 89 by means of a guide rod 161 slidable in a hole 163 in the bracket. Carriage 157 is movable up and down for adjustment by means of an adjustment rod 165 mounted as indicated at 167 for rotation in bracket 159 and threaded into a tapped hole 169 in the carriage, and the rod has a knob 171 at its upper end for turning it for adjustment upon loosening a lock nut 173. Mandrel adjusting stem 109 has a collar 175 adjacent its upper end received in a groove 177 in carriage 157, and this arrangement permits rotation of stem 109 while enabling up and down adjustment of the stem and mandrel 99 by the carriage. For in and out adjustment of bending guide 131, slide 141 carrying the guide is slidable in and out on rods 143 by a cam bar 179 extending downwardly from carriage 157 through a hole 181 in bracket 159. Cam bar 179 has an angled lower end portion 183 forming a cam slidable in an angled slot 185 in slide 141, and which extends downwardly into a notch 186 in guide 131. Thus, upon upward movement of carriage 157 and cam bar 179, slide 141 and bending guide 131 are moved inwardly toward mandrel 99 a distance corresponding to the concomitant decrease in the effective winding diameter of mandrel 99 and vice versa. The mandrel and guide adjustment, as described, is a manual adjustment. It may be automated, as will be later described. Also, it is contemplated that the interconnection of carriage 157 and the mandrel adjusting stem may be omitted and the mandrel and guide adjustments may be made independently of one another within the scope of the invention so as to meet at least some of the objects thereof.

As illustrated in FIGS. 5 and 10, the aforesaid drive 117 is taken off press shaft 35, and includes variable drive means, such as a speed changer 185 or the like for instance preferably of the differential type, having an input shaft 187, an output shaft 189, and a speed change shaft 191. Input shaft 187 is adapted to be constantly rotated or continuously driven at a speed or rate related to the press shaft speed by a chain and sprocket drive 193 from press shaft 35. Mounted on a platform 194 on top of upper frame plate 81 is a right angle drive 195 having a horizontal input shaft 197 driven by a chain and sprocket drive 199 from speed changer output shaft 189 and a downwardly extending output shaft 201. At 203 is indicated a chain and sprocket drive taken off right angle drive output shaft 201 and driving pinch wheel shaft 123 of winder 77A. Pinch wheel shaft 123 has a gear 205 in mesh with spindle gear 115 for driving spindle 85 of winder 77A.

From the above and as may be best seen in FIGS. 9 and 11-13, it will appear that in winder 77A strip 5A is bent to form it into a helix or helical convolutions by bending guide 131 around mandrel 99 in winding plane P at the bottom face of friction drive wheel 95. Strip 5A is guided in a horizontal path in winding plane P between the inside (upper) face of bending guide flange 133 and bottom face 97 of wheel 95. With bending guide 131 biased by springs 151 in the direction toward wheel 95 (upwardly), the opposite faces of strip 5A generally at yoke section or continuous band portion 7 thereof are confined flatwise at 139 between the upper face of the flange and the bottom face of drive wheel 95 to prevent the strip from buckling, and the opposite edges of the strip are confined between bending edge 137 of guide 131 and conic surface 103 of mandrel 99, being thereby constrained to be bent edgewise around the mandrel and formed into a helix. Flange 133 may be relieved, as indicated at 206 in FIG. 13, so that teeth 9 of strip 5A are not contacted by the flange. As strip 5A exits from bending guide 131, it (more particularly its opposite faces or band portion 7) remains confined flatwise between wheels 119 and 95 so as to be gripped thereby, but as the strip passes by wheel 119, the strip is released from confinement so that each helical convolution generated from the strip is released from confinement for helical progression of the helical convolutions downwardly away from mandrel 99 and sheel 95 for accumulation in a generally axial and generally annular stack thereof to form an edgewise wound core C wherein the convolutions lie flatwise one on another, as seen in FIGS. 9 and 11. The successive helical convolutions progress helically downwardly away from mandrel 99 and wheel 95 surrounding what may be termed a split arbor or receiving and accumulating means generally designated 207 associated with the mandrel on winder axis A.

Split arbor 207 comprises a pair of relatively movable means adapted for separation, such as for instance an upper arbor section or receiving means 209 which is secured to mandrel 99 for rotation therewith on winder (mandrel) axis A and a lower arbor section or stripping arbor, such as for instance, a separable or accepting means 211 or the like, which receives the helical convolutions in the axial stack thereof forming an edgewise wound core C. Lower arbor section 211 is separable from upper arbor section 209 by displacing or moving it downwardly toward a displaced or separated position away from the upper section for removal of an edgewise wound core C. As shown in detail in FIGS. 8 and 9, upper arbor section 209 is a hollow, generally cylindric and elongate sleeve closed at its upper end, as indicated at 213, and secured at its upper end to spindle extension 111, as indicated at 215. Upper arbor section 209 is shown in FIG. 9 as having a somewhat larger diameter than the lower end of mandrel 99 (the small end of the mandrel) with a slight taper 217 extending from the upper end downwardly to the diameter of the lower end of the mandrel to facilitate the downward progression of the helical convolutions of the strip off the mandrel away from wheel 95 and into generally loose surrounding relation with respect to the split arbor.

Lower arbor section 211 is also a generally cylindric and elongate sleeve or member of generally the same diameter as the main body of upper arbor section 209 and arranged generally in axial alignment therewith. Lower arbor section 211 is conjointly movable with an elevator 223 on which it is mounted for rotation about winder axis A by means of a bearing 225. The arrangement is such that lower arbor section 211 is movable upwardly into its raised or at-rest position, as illustrated in solid lines in FIGS. 7 and 9, wherein the upper or free end of the lower arbor section is in engagement with the lower or free end of upper arbor section 209, and elevator 223 is operable to move the lower arbor section downwardly to its displaced or lowered position, as illustrated in FIG. 4. Elevator 223 is reciprocally movable to move lower arbor section 211 between its raised and lowered positions by means of an air cylinder 231 secured to the bottom of frame plate 83 so as to extend downwardly from the latter, and a piston rod 233 of the air cylinder extends through a hole 235 in the plate into connection at 237 with the elevator. The latter is guided for its stated up and down movement by means of guide rods 239 extending from the elevator and slidable in bushings 241 in plate 83.

Lower arbor section 211 has an outwardly extending flange or supporting means 243 at its lower end forming a ledge on which the axial stack of helical convolutions for forming an edgewise wound core C rests, and the outside diameter of flange 243 may be, if desired, substantially less than the outside diameter of the axial stack or core so that the latter projects beyond the flange. Elevator 223 has a base 223a and an upwardly extending hollow cylindric housing 244 for bearing 225. When elevator 223 is in its raised position of FIG. 7 holding lower arbor section 211 in its raised position, cylindric housing 244 is situated in an opening 245 in a core transfer carriage 247 mounted for horizontal sliding movement transversely with respect to axis A of winder 77A. Carriage 247 is movable between a retracted position, as illustrated in solid lines in FIG. 7, and an advanced position, as illustrated in phantom in FIG. 7, on a set of horizontal guide rods 219 mounted in the frame structure of the apparatus, as illustrated in FIGS. 4 and 5. Carriage 247 is movable between its stated retracted and advanced positions by means of an air cylinder 251 secured to a vertical frame plate 253, and a piston rod 255 of the air cylinder extends through a hole 257 in this plate into a connection at 259 with the carriage.

Strip 5A, after having been bent or deformed to form the helical convolutions, progresses helically downwardly around the circumferential surface of split arbor 207 of winder 77A and travels through a strip cutter or severing means indicated generally at 261 in FIGS. 15 and 16 for cutting the strip when the accumulated thicknesses of the helical convolutions in an axial stack thereof defining an edgewise wound core C attain the preselected stack height therefor. Cutter means 261 includes a pair of rotary cutters 263, 265 mounted for rotation adjacent each other on generally parallel inclined axes in a cutter frame 267 mounted on an inclined mounting plate 269 carried by a bracket 271 on plate 81, and these cutters are located just below drive wheel 95 in position for travel of the just-bent helical convolutions of strip 5A therebetween as such helical convolutions pass from between wheels 95, 119.

As appears in FIGS. 7 and 9, the helical convolutions accumulate in an axial stack thereof on flange 243 of lower arbor section or core receiver 211 of winder 77A, and the helical convolutions extend in spaced apart relation axially (vertically) generally from rotary cutters 263, 265 down to those helical convolutions already accumulated in the generally axial stack thereof on flange 243, as appears in FIGS. 7, 9 and 15. Cutters 263, 265 are rotated to cut the strip, as will be described, when the accumulated thicknesses of the helical convolutions defining an edgewise wound core C attains the preselected stack height, and those trailing helical convolutions which extend from the cutters down to the already-stacked helical convolutions drop down as indicated by the arrow at the lower left of FIG. 15 to complete the flatwise stacking of the helical convolutions and the formation of an edgewise wound core C. It will be understood that respective ones of edgewise wound cores C will have what is referred to as a yoke section formed by band 7 of the helical convolutions in the axial stack thereof with such yoke section generally defining a circumferential portion of such cores, and strip 5A and teeth 9 extend radially inwardly from the band to form at least in part a bore 275 through the core with slots 11 being disposed between the teeth. At this stage, teeth 9 and lands 57 of adjacent helical convolutions of a core C may be angularly displaced one from another, as illustrated in FIGS. 17 and 18, but the convolutions are easily rotatable one relative to another to align the teeth and slots 11 generally axially between opposite end faces of the core in the course of final operations on the core as is well known to the art.

Upon the cutting of strip 5A by cutters 263, 265 in winder 77A to complete the formation of an edgewise wound core C on flange 243 of core receiver or lower arbor section 211, elevator 223 is moved downwardly thereby to conjointly move the lower arbor section therewith, and upon such conjoint downward movement, core C carried on the lower arbor section engages carriage 247 generally about opening 245 therein, and such core is thereby stripped from the lower arbor section as the latter is moved downwardly to its lowered retracted position, as shown in FIG. 4, below carriage 247 thereby to define a means for stripping the core from the lower arbor section. Thus, with a core C so deposited on carriage 247 and with lower arbor section 211 in its retracted position, the carriage is moved from the at-rest position to the advanced position thereof, as shown in solid lines in FIG. 4 and in phantom in FIG. 7, by cylinder 251 to bring the core C to a discharge or displacement position in the path of a means for displacing the core, such as a core ejector 277 or the like for instance. The latter comprises a core pusher slidably movable on guide rods 279 in the frame structure from a retracted position, as illustrated in solid lines in FIG. 4, to a protracted or core displacing position, as illustrated in phantom in FIG. 4, for pushing the core from carriage 247 onto a means for receiving the core and for effecting the movement thereof from the apparatus, such as for instance a roller conveyor 281 or the like sloping downwardly in an apparatus exiting direction. Core pusher 277 is reciprocally movable by means of an air cylinder 283 having its piston rod 285 connected to the core pusher at 287.

When strip 5A is cut upon the formation of an edgewise wound core C from the helical convolutions of the strip, as discussed above, the leading end of the cut helical convolution coils around upper arbor section 209 without interruption. To prevent the trailing end of the cut helical convolution and the oncoming helical convolution from falling from upper arbor section 209 when lower arbor section 211 is separated therefrom, upper arbor section 209 is provided with supporting means comprising a set of pins 289 (see FIGS. 8 and 9) slidable radially with respect to the upper arbor section into and out of openings or holes 290 in the upper arbor section adjacent its lower end. Pins 289 have heads 291 at their inner ends within a chamber in upper arbor section 209, each of these pin heads being shaped on its outwardly facing side to provide a camming surface 293. Pins 289 are biased to slide radially outwardly relative to upper arbor section 209 toward protracted positions so that the free ends or free portions of the pins extend beyond the circumferential surface of the upper arbor section by a set of springs or spring means 295 respectively retained in a spider 297 secured within the upper arbor section by screws 298. At 299 is indicated a cam or camming means for camming pins 289 inwardly to a retracted position wherein their outer or free ends are disposed within holes 290 out of the way of the helical convolutions of strip 5A progressing helically downwardly about the circumferential surface of the upper arbor section. Cam 299 is cup shaped, having a circular bottom 301 and an upwardly extending peripheral wall 303 which is slidable upwardly and downwardly in the chamber within the upper arbor section 209 generally adjacent its lower end. Peripheral wall 303 of cam 299 has notches 305 receiving pins 289 and is beveled at its upper edge to provide a camming surface 307 cooperable with camming surfaces 293 of the pin heads. Cam 299 is secured to the lower end of a plunger 309 vertically slidable in spider 297, the plunger and cam being biased downwardly toward an at-rest position by a compression spring or resilient or urging means 311 reacting from upper end 213 of upper arbor section 209 against a head 313 on the plunger. Thus, in its at-rest position, cam 299 is biased into seating engagement with upper arbor section 209 at least generally adjacent its lower end thereby to define a means for caging the cam and spring 311. A plug 315 secured on a shoulder 317 adjacent the upper or free end of lower arbor section 211 is engageable with the bottom of cam 299 when the lower arbor section is raised to hold the cam up in the raised or camming position thereof, as illustrated in FIG. 9, wherein the bottom of the cam is flush with the lower or free end of upper arbor section 209. Cam 299, when it its raised position disposes camming surface 307 thereof in camming engagement with camming surfaces 293 of pins 289 so as to cam or hold the pins in their retracted positions (shown in solid lines in FIGS. 8 and 9) thereby to permit downward progression or transfer of the helical convolutions from upper arbor section 209 to lower arbor section 211. When lower arbor section 211 is pulled down to its lowered retracted position by elevator 223, as previously mentioned, cam 299 is driven downwardly toward its at-rest position by spring 311, and springs 295 bias or resiliently urge pins 289 radially outwardly with respect to upper arbor section 209 so that the free ends of the pins protrude therefrom adjacent its lower end, as shown in phantom in FIGS. 8 and 9, for seating and supporting at least some of the oncoming helical convolutions thereby to prevent them from dropping off the lower end of the upper arbor section until such time as lower arbor section 211 is reassociated in aligned relation therewith to receive the helical convolutions. On raising the lower arbor section to its at-rest position, the free end thereof abuts cam 299 moving it upwardly toward its camming position to effect the retraction of pins 289.

Each of cutters 263, 265 is of short cylindrical form with a helicoidal cutting tooth 317 thereon (see FIG. 16), and the cutters are mounted on the ends of cutter shafts 319, 321 journalled in cutter frame 267, respectively. Shafts 319, 321 and cutters 263, 265 thereon are adapted to be driven through a single revolution for cutting strip 5A passing between the cutters by means of a drive 323 including a single-revolution clutch 325 having its output shaft 327 connected to cutter shaft 321, the latter being geared to cutter shaft 319 at 329. At 331 is indicated a solenoid for activating clutch 325 to drive its output shaft 327 and thereby cutter shafts 319, 321 through a single revolution for a cutting operation. An input shaft 335 of clutch 325 is continuously driven via a right-angle drive 337 having its input 339 driven via a pinion 341 in mesh with gear 115 and its output 343 connected via an angle drive 345 to a chain and sprocket drive 347 connected to clutch input shaft 335.

Solenoid 331 of single-revolution clutch 325 is connected in a control circuit, as shown in FIG. 3, with strip thickness sensor 73 controlling operation of the solenoid to trigger clutch 325 for cutting strip 5A when the accumulated thicknesses of the helical convolutions of the strip which have travelled between cutters 263, 265 is such as to provide the preselected stack height (axial dimension) for an edgewise wound core C. It will be readily understood that the stack height of a core C generally equals the accumulated sum of at least some of the individual convolution thicknesses which, as previously mentioned, varies along the length of the strip. In the control circuit, each signal from strip thickness sensor 73, this signal being related to variations in the strip thickness, is fed as indicated at 349 to a signal conditioning and digital readout device 351 such as a Non Contact Gaging System sold by Kaman Science Corp. of Colorado Springs, Colo. The latter amplifies the signal, and as indicated at 353, feeds a DC signal which is proportional to the strip thickness to a waveform analyzer 355 such as a Data 6000 sold by Data Precision Corp. of Danvers, Mass. The latter functions to generate a digital signal based on the average of a relatively high number of thickness readings at the press 19 (e.g., the average of 330 readings), and this signal is fed as indicated at 357 to a computer 359, such as a model 9816 sold by Hewlett Packard Corp. of Palo Alto, Calif. The latter functions to test the signal for validity, i.e., with respect to a preselected value or norm and the previous reading, sums at least some of the valid signal values (i.e., adds at least some of the valid thickness measurements and divides by a preselected number) to generate a total corresponding to the accumulated thickness of the helical convolutions since the last cut, compares the total or sum to a target value corresponding to the preselected stack height to an edgewise wound core C to be produced, and delivers a cut signal via a line 361 to a programmable controller 363 when the sum reaches the target value. Controller 363, is programmed to hold the signal, until it receives an input via a line 365 from a tooth position sensor or sensing means 367, which may be an infrared light sensor sold by Sick Corp. of Munich, West Germany, adjacent the strip cutters that a portion of band 7 of strip 5A between two adjacent teeth 9 of the strip, i.e., a portion of the band generally in line with a slot 11 of the strip, is between the cutters. This insures that the cut is made between teeth 9, where it will completely sever strip 5A, as distinguished from being made in line with a tooth, where it might not completely sever the strip.

As appears in FIGS. 5 and 6, axis A of winder 77A is offset to the left of the center line of the two strips as viewed in the direction of travel of the strips (downstream direction), and it winds strip 5A (which is the right-hand strip of the two strips 5A, 5B as viewed in downstream direction) in a counterclockwise direction. Winder 77B is situated downstream from winder 77A with its axis A offset to the right of the center line of the strips (again in reference to downstream direction) and winds strip 5B in a clockwise direction. Aside from this difference, and a difference in the core discharge means to be explained hereinafter, winders 77A, 77B are basically identical. Parts of winder 77B corresponding to parts of winder 77A are assigned the same reference numerals. As to the core discharge means of winder 77B, as best seen in FIG. 4, a stationary platform 371 replaces carriage 247 associated with winder 77A. Upon the cutting of strip 5B in winder 77B, elevator 223 of the winder is moved down to move core receiver 211 of the winder down. A formed core C carried on receiver 211 then engages platform 371 being seated around an opening 373 in the platform and is stripped from receiver 211 as the latter moves down to its retracted position wherein its upper or free end is below the platform. Thus, the core is placed on platform 371, and with core receiver 211 clear of the platform, the core is displaced or pushed from the platform by a core pusher 277 (corresponding to that of winder 77A and similarly operated by an air cylinder 283) and onto a second roller conveyor 375 sloping downwardly in exit direction for core discharge.

Winder 77B is driven via chain and sprocket drive 193, speed changer 185, chain and sprocket drive 199, right angle drive 195 and chain and sprocket drive 203, the latter including an idler sprocket 377 on a pedestal 379 on top plate 81 and a sprocket 381 on spindle 85 of winder 77B. Speed changer 185 is under control of the looped portion 17 in strips 5A, 5B for increasing the continuous rate at which the strips are moved by winder 77A, 77B relative to the intermittent rate at which the strips are fed out of press 19 into the looped portion upon increases in the size of the looped portion to an upper limit and for decreasing the continuous rate at which the strips are moved by the winders relative to the intermittent rate at which the strips are fed out of the press into the looped portion upon decreases in the size of the looped portion to a lower limit. The increase and decrease of the winding rate of strips 5A, 5B, i.e., the variable continuous speed of winders 77A, 77B, is effected by controlling speed changer 185 to increase its output speed on increase in the size of looped portion 17 to an upper limit determined by an upper limit sensor 383 and to decrease its output speed on decrease in the size of the looped portion to a lower limit determined by a lower limit sensor 385. These sensors are interconnected as indicated at 387 and 389 in FIG. 1A with a control 391 for a speed changer motor 393 connected by a chain and sprocket drive 395 (see FIG. 5) to speed changer shaft 191. The system is such that when the upper sensor 383 senses increases in the size of the looped portion 17 to the upper limit, it transmits a signal to a control 391 for motor 393 to effect operation of motor 393 for driving shaft 191 to increase the speed of the changer output shaft 189 thereby to increase the speed of winders 77A, 77B. And when the lower sensor 385 senses decreases in the size of looped portion 17 to the lower limit, it transmits a signal to control 391 to effect deenergization of the motor 393 thereby to decrease the speed of the winders. With motor 393 deenergized, the size of loop 17 increases until sensed by upper sensor 383 thereby to reinitiate the system for effectively decreasing the loop size, as previously discussed; however, to accomplish this type of control, it is desirable that the intermittent rate at which press 19 is operated be at least slightly greater than the normal variable rate at which winders 77A, 77B are operated. Sensors 383 and 385 may be induction proximity sensors, activated by proximity thereto of strips 5A and 5B in the loop 17 of a type well known to the art sold by Veeder Root Co. of Hartford, Conn. Albeit not shown herein, it is believed that when lower sensor 385 senses the decrease in size of loop 17 to the lower limit thereof, the lower sensor may signal controller 391 to effect the operation of motor 393 in the opposite direction to decrease the speed of the changer output shaft thereby to decrease the speed of winders 77A, 77B within the scope of the invention so as to meet at least some of the objects thereof.

Air cylinders 231, 283 and 251 for elevators 233 and core ejectors 277 of winders 77A, 77B and carriage 247 of winder 77A are shown in FIG. 3 are connected in a pneumatic circuit including a solenoid valve for 399 controlling cylinders 231, a solenoid valve 401 for controlling cylinders 283, and a solenoid valve 403 for controlling cylinder 251. Operation of these valves is controlled by programmer 363. Programmer 363 is interconnected with solenoid valves 399, 401 and 403 and acts in response to the cut signal (which results in cutting of the strips thereby to complete the formation of an edgewise wound core C as previously discussed) to actuate elevator cylinders 231 for lowering of core receivers 211 and stripping the formed cores therefrom (leaving the core formed in winder 77A on carriage 247 and the core formed in winder 77B on platform 371), followed by actuation of cylinder 251 to drive carriage 247 carrying the core formed in winder 77A to its advanced position (see FIG. 5) in front of core ejector 277 of winder 77A, followed by action of the ejector cylinders 283 to drive core ejectors 277 forwardly to push the cores onto conveyors 281, 283, and then followed by return actuation of the cylinders to return the core ejectors and carriage to their retracted positions and the elevators to their raised position.

In order to set up the apparatus for the continuous formation of edgewise wound cores C, strip stock 3 is unwound from supply 13 thereof, entrained between feed rolls 41, and between press head 31 and die 25, and press 19 is placed in operation or jogged with accompanying intermittent forward feed of the strip stock by the feed rolls through the press and the lancing of the strip stock in the press into strips 5A, 5B. Operation of press 19 is continued until a sufficient length of strip 5B has been generated to reach to winder 77B, and the press is then stopped. This also generates more than a sufficient length of strip 5A to reach to winder 77A and the excess length of strip 5A is manually cut off.

With press 19 and winders 77A, 77B stopped, the leading end of strip 5A is temporarily attached to drive wheel 95 of winder 77A, as illustrated in FIG. 9, by means of a pin 409 removably mounted in a hole 411 as by means of set screw indicated at 413 in the friction drive wheel and extending downwardly therefrom into a hole made in the leading end of band portion 7 of the strip. Pin 409 extends only slightly from bottom surface 97 of wheel 95 so that it does not extend beyond strip 5A. The leading end of strip 5B is similarly temporarily attached to wheel 95 of winder 77B. Then, press 19 is jogged to jog winders 77A, 77B and thereby draw strips 5A, 5B around through bending guides 131 of the winders to the point where the leading end of each strip and the respective pins 409 are past the respective pinch wheels 119. To complete the setup of the apparatus, press 19 is again stopped to stop both winders, and pins 409 are removed to free strips 5A, 5B for the downward helical progression onto the respective split arbors 207 of the helical convolutions into which the strips are formed. It is contemplated that the above discussed set up of the apparatus may be effected for each roll of stock 3 introduced to the apparatus, and it is also contemplated that means, such as a laser welder or the like for instance, may be utilized in conjunction with such apparatus to interconnect the trailing end of a roll of stock with a leading end of a successive roll of stock so as to continually supply stock to the apparatus thereby to obviate successive setups thereof to accept each roll of stock, as mentioned above, within the scope of the invention so as to meet at least some of the objects thereof.

With loop 17 formed in strips 5A, 5B, operation of press 19 is resumed, and the apparatus may be thereafter continuously operated to effect the continuous formation of edgewise wound cores C, as discussed hereinafter. Strip stock 3 is intermittently fed by feed rolls 41 in increments equal to one-fourth the length of a helical convolution into which each strip is edgewise wound; however, it is contemplated that other feed increments may be employed within the scope of the invention so as to meet at least some of the objects thereof. In its dwell intervals between the feed intervals, strip stock 3 is punched or lanced as has been described into strips 5A, 5B. These two strips, divided one from the other by reason of the punching operation, but still in interdigitated relation, feed intermittently from die 25 out from under press head 31 and punches 29 into looped portion 17 of the strips.

With the leading end of strips 5A, 5B having been drawn through bending guides 131 of winders 77A, 77B and past pinch wheels 119 thereof and with pins 409 removed, the aforementioned setup of the apparatus is complete, and the apparatus may be thereafter continuously operated to effect the continuous formation of edgewise wound cores C. Upon the continuous operation of the apparatus, winders 77A, 77B are conjointly driven continuously off press 19 to effect continuous edgewise winding of strips 5A, 5B. The drive for both winders is from press shaft 35, which runs continuously, via speed changer 185. The looped portion 17 in strips 5A, 5B is such as to enable continuous feed of the strips from the looped portion to winders 77A, 77B between intermittent successive feed cycles of strip stock 3 and during such intermittent feed cycles for the continuous winding of the strips. Upon an increase in the size of looped portion 17 as sensed by upper sensor 383, the upper sensor transmits a signal to control 391 for speed change motor 393 to effect operation of this motor to increase the speed of output shaft 189 of speed changer 185 thereby increasing the speed of both winders 77A, 77B and hence the continuous rate at which strips 5A, 5B are wound relative to the intermittent rate at which such strips are fed from press 19 into the looped portion in order to reduce the size of the looped portion from the upper limit as determined by upper sensor 383. Upon decreases in the size of looped portion 17 as sensed by the lower sensor 385, the lower sensor transmits a signal to control 391 for speed change motor 393 to effect operation of this motor to decrease the speed of output shaft 189 of speed changer 185 thereby decreasing the speed of winders 77A, 77B and hence the continuous rate at which strips 5A, 5B are wound relative to the intermittent rate at which such strips are fed from press 19 into the looped portion in order to increase the size of the looped portion from the lower limit determined by the lower sensor. Thus, looped portion 17 is maintained within the limits determined by sensors 383, 385 without becoming too small or too large.

Each of the strips 5A, 5B is continuously wound edgewise into a plurality of generally helical convolutions thereof in the respective winders 77A, 77B by being drawn through the respective bending guides 131 of the winders by reason of band portion 7 of the strip being pinched or grippingly engaged between the respective drive wheel 95 and pinch wheel 119 of the winders, both these wheels being continuously driven. Wheel 119 applies pressure to band portion 7 of the strip to hold it flatwise against bottom surface 97 of drive wheel 95, and the frictional engagement between the opposite faces of the strip generally at band portion 7 thereof with drive wheel 95 and pinch wheel 119 is such as to effect the drawing of the strip through bending guide 131. As the strip is drawn through bending guide 131, its band portion 7 is constrained flatwise at 139 between flange 133 of the bending guide and bottom surface 97 of wheel 95, i.e., the strip is confined at both opposite faces thereof between 133 and 97, to prevent buckling. Also, the strip is confined at its opposite edges, more particularly at the outer opposite edge on lands 57 by bending edge 137 of the bending guide and at the inner opposite edge at the tips of teeth 9 by the surface of conic portion 103 of mandrel 99. In being drawn through bending guide 131, the strip is bent edgewise to form the continuous helical convolutions, each having a diameter corresponding to the diameter of the conic surface on mandrel 99 in plane P, as it reaches the end of portion l37b of the bending edge 137 of the bending guide. As each helical convolution exits from bending guide 131 it is released from its stated confinement at its outer edge and, when so released, may tend to spring back outwardly to a larger diameter. The spring-back is measured, e.g., when the winding is stopped to remove the pins 409 during the above discussed setup of the apparatus, and each mandrel 99 and each bending guide 131 are adjusted by turning the respective knob 171 to make the effective mandrel diameter, i.e., the diameter of conic section 103 of the mandrel in plane P, correspond to the final internal diameter (after spring-back) desired for the cores C. Bending guide 131 is also adjusted to space bending edge 137b thereof from the conic surface 103 of the mandrel in plane P a distance corresponding to the overall width of the strip, thereby to achieve the edgewise confinement of the strip. The net effect of this is that each strip is wound into helical convolutions which have a preliminary diameter (internal or external) less than the final diameter (internal or external) by the amount of spring-back. Then upon release from edgewise confinement, each convolution springs out (i.e., expands) to the final or preselected diameter greater than the preliminary diameter.

Generally, the adjustment for spring-back of each strip is made during the setup of the apparatus, as previously mentioned at the start of winding strips 5A, 5B generated from each coil 13 of strip stock 3, and it may also be made from time-to-time during the continuous operation of the apparatus as conditions may require. Further, and as also previously mentioned, it will be understood that when the end of one coil 13 is reached, the leading end of the next coil may be attached thereto by suitable means for continuing the operation without a setup of the apparatus, and the spring-back of material from such next coil generally will be initially measured and the necessary mandrel and guide adjustment made.

In each of the winders 77A, 77B, the helical convolutions of the respective strip edgewise wound thereby are released from confinement as they travel around the respective mandrel 99 and exit from the respective pressing zone 130 (i.e., from between wheels 95, 119). The progressively formed helical convolutions then progress helically downwardly away from mandrel 99 and away from bottom surface 97 of wheel 95 to encircle split arbor 207 and accumulate in an axial stack on flange 243 of lower arbor section 211, as appears to advantage in FIG. 9. As the helical convolutions pass from between wheels 95, 119 and travels helically downwardly off mandrel 99, the helical convolutions pass between rotary cutters 263, 265 (see FIG. 15). Computer 359 analyzes the thickness measurements made in press 19 by thickness sensor 73, as previously discussed, and when such analyzed thickness measurements attain a value correlative with the preselected stack height for an edgewise wound core C, the cut signal is transmitted via line 361 to controller 363. Under control of sensor 367, controller 363 delays the energization of cutter solenoid 331, if need be, until a portion of band portion 7 of the strip between two adjacent teeth 9 of the strip is between cutters 263, 265. Then cutter solenoid 331 is energized to rotate cutters 263, 265 and cut the strip between teeth so as to completely sever it. The cut line is as indicated at 415 in FIGS. 17 and 19. When the strip is cut, those convolutions below the cut which extend from the cutter means down to the convolutions accumulated in the axial stack thereof on flange 243 fall down on top of the stack (pins 289 of the upper arbor section 209 being retracted at this point in time) to complete the production or formation of an edgewise wound core C. In each winder, the completed helix or core bears on the flange 243 of the core receiver 211 (which is in raised position), the core surrounding the receiver.

The signal to the cutter solenoid is also transmitted via another output of controller 363 through line 407 to the pneumatic circuit (see FIG. 3). Controller 363 then functions first to actuate valve 399 to actuate the elevator cylinders 231 to retract their piston rods and thereby lower elevators 233 and core receivers 211 thereon. As elevator 233 and core receiver 211 of winder 77A go down, core C on this core receiver is deposited onto carriage 247 (which is in its retracted position) and thereby stripped from the core receiver. As elevator 233 and core receiver 211 of winder 77B go down, the core C on this core receiver is deposited onto platform 371 and thereby stripped from the core receiver.

As each core receiver 211 goes down and its upper end disengages from the respective cam 299, the latter is released to move down under the bias of spring 311, with the result that pins 289 are projected to extend radially outwardly from the upper arbor section 209 adjacent its lower end as shown in phantom in FIGS. 8 and 9 for supporting at least some of the oncoming helical convolutions and preventing them from dropping off the lower end of the upper arbor section until the receiver is moved back up to receive the convolutions.

The controller 363 also functions through still another output thereof and a line 407a to actuate valve 403 to actuate carriage cylinder 251 to extend its piston rod and move carriage 247 to its advanced position shown in FIG. 5 thereby bringing the core C on the carriage in front of ejector or pusher 277 of winder 77A. Then the controller 363 functions through another of its outputs and a line 407b to actuate valve 401 to actuate cylinders 283 to retract their piston rods and drive ejectors or pushers 277 through a working stroke to push the first core C off carriage 247 onto conveyor 375. Then the controller functions to actuate the valves and cylinders in the reverse sequence to return the pushers to their retracted position, the carriage to its retracted position, and the elevators and core to their raised position. To complete the operation of the apparatus, when the elevators and receivers are raised, cams 299 are actuated to their camming positions by the receivers thereby to return pins 289 to their retracted position, clearing each upper arbor section 209 for travel or translation of the helical convolutions accumulated thereon into seating engagement with flange 243 on the respective receiver 211.

Referring now to FIGS. 21-23, there is shown an alternative apparatus for continuously forming edgewise wound cores which may be utilized in an alternative method for continuously forming edgewise wound cores in one form of the invention, and the alternative apparatus has generally the same component parts functioning generally in the same manner as those of the previously described apparatus with the exceptions discussed hereinafter. While the alternative method meets at least some of the objects set out herein, it is believed that such alternative method may have additional objects and advantageous features which will be in part apparent and in part pointed out in the following discussion.

In FIGS. 21-23, it may be noted that the speed of each winder 77A, 77B of the alternative apparatus is individually controlled instead of being under common control. For this purpose, the drive via 203 from winder 77A to winder 77B is omitted. Pinch wheel shaft 123 of winder 77A is driven from shaft 201 via a chain and sprocket drive indicated at 415. Winder 77B has its own drive 117B from an extension 35A of press shaft 35, similar to drive 117 for winder 77A, including a speed changer 185B corresponding to speed changer 185, having an input shaft 187B, an output shaft 189B, and a speed change shaft 191B. Input shaft 187B is adapted to be constantly driven at a speed related to the press shaft speed by a chain and sprocket drive 193B from press shaft extension 35A. At 195B is indicated a right angle drive corresponding to 195 having a horizontal input shaft 197B driven by a chain and sprocket drive 199B from speed changer output shaft 189B and a downwardly extending output shaft 201B. The latter is connected to drive pinch wheel shaft 123 of winder 77B via a chain and sprocket drive 415B.

Referring to FIG. 22, it will be observed that instead of operating with a single loop comprising a loop of strip 5A and a loop of strip 5B on passage of the strips from die 25, operation proceeds with an individual loop 17A of strip 5A and an individual loop 17B of strip 5B. One of these is directed upwardly and the other downwardly, and as shown, loop 17A is the one directed downwardly and loop 17B is the one directed upwardly. A pair of sensors 383A, 385A are provided for loop 17A, and another pair of sensors 383B, 385B are provided for loop 17B. Speed changer 185 of winder 77A is under control of sensors 383A, 385A, and speed changer 185B of winder 77B is under control of sensors 383B, 385B. Sensors 383A, 385A are interconnected as indicated at 387A, 389A in FIG. 23 with control 391A for reversible speed changer motor 393A connected by chain and sprocket drive 395A (FIG. 21) to speed changer shaft 191 of winder 77A. Sensors 383B, 385B are interconnected as indicated at 387B, 389B in FIG. 23 with control 391B for reversible speed changer motor 393B connected by chain and sprocket drive 395B (FIG. 21) to speed changer shaft 191B of winder 77B. The system is such that when sensor 383A senses an increase in the size of loop 17A to the upper limit of the size of this loop, it transmits a signal to a control 391A for motor 393A to effect operation of motor 393A in the direction for driving shaft 191B to increase the speed of changer output shaft 189B thereby to increase the speed of winder 77B, which decreases the size of the loop. When sensor 385A senses a decrease in the size of the loop 17A to the lower limit of the size of the loop, it transmits a signal to control 391A to effect the deenergization of motor 393 thereby to decrease the speed of winder 77A which effects an increase in the size of the loop. Similarly, when sensor 383B senses an increase in the size of loop 17B to the upper limit, it transmits a signal to control 391B for motor 393B to effect operation of motor 393B in the direction for driving shaft 191B to increase the speed of changer output shaft 189B thereby to increase the speed of winder 77B which effects a decrease in the size of the loop. When sensor 385B senses a decrease in the size of loop 17B to the lower limit, it transmits a signal to control 391B to effect the deenergization of motor 393B thereby to decrease the speed of winder 77B which effects an increase in the size of the loop.

From the foregoing, it is now apparent that novel methods for forming edgewise wound cores have been presented meeting at least the objects set out hereinbefore, and it is contemplated that changes as to the precise arrangements, shapes, connections and other details of the constructions illustrated herein for purposes of disclosure, as well as the precise steps and orders thereof of such methods, may be made by those having ordinary skill in the art without departing from the spirit of the invention or from the scope thereof as defined by the claims which follow. 

What I claim as new and desire to secure by Letters Patent of the United States is:
 1. A method of forming edgwise wound cores at at least one winding station from a continuous strip of a generally thin ferromagnetic material, the at least one winding station having a means for receiving the edgewise wound cores with the receiving means including a pair of arbor means adapted for engagement with each other in one position and with one of the arbor means being movable toward another position disengaged from the other of the arbor means, the method comprising the steps of:forming the continuous strip into one of the edgewise wound cores generally about the receiving means therefor at the at least one winding station and supporting the one edgewise wound core at least during the formation thereof on the one arbor means when the arbor means are engaged in the one position thereof; severing the one edgewise wound core upon the formation thereof from the continuous strip and moving the one arbor means with the one edgewise wound core supported thereon from the one position toward the another position disengaged from the other arbor means; and continuing the formation of the at least one continuous strip into at least a part of another of the edgewise wound cores generally about only the other arbor means and effecting support of the at least part of the another edgewise wound core on the other arbor means in response to the disengagement therefrom of the one arbor means.
 2. The method as set forth in claim 1 further comprising the additional step of stripping the one edgewise wound core from the one arbor means when the one arbor means is in the another position.
 3. The method as set forth in claim 2 further comprising the further additional step of displacing the at least one edgewise wound core from the at least one winding station.
 4. The method as set forth in claim 2 further comprising the further additional step of returning the one arbor means toward the one position and reengaging the one arbor means with the other arbor means while the at least part of the another edgewise wound core is being supported thereon.
 5. The method as set forth in claim 4 further comprising the still further additional step of effecting the transfer of the at least part of the another edgewise wound core on the one arbor means while continuing the formation of the at least one continuous strip into the another edgewise wound core about the receiving means.
 6. A method of continuously forming edgewise wound cores from a continuous strip of a generally thin ferromagnetic material at at least one winding station having a pair of arbor means for engagement with each other and for disnegagement from each other, and a set of supporting means in one of the arbor means and adapted for displacement toward a protracted position extending beyond the one arbor means, the method comprising the steps of:deforming the continuous strip generally edgewise thereof onto a plurality of generally helical convolutions thereof and accumulating the helical convolutions in a generally axial stack thereof about the arbor means when the arbor means are engaged; severing a respective one of the helical convolutions without interrupting the progressive deformation of the continuous strip into the helical convolutions thereof at least generally when the axial stack attains a preselected stack height and defining thereby a respective one of the edgewise wound cores on the other arbor means; disengaging the other arbor means with the respective one edgewise wound core supported thereon from the one arbor means and effecting the displacement of the supporting means toward the protracted postion thereof extending beyond the one arbor means in response to the disengagement therefrom of the other arbor means; and receiving on the supporting means in the protracted positions thereof at least some of the successive ones of the helical convolutions following the severed respective one convolution and accumulating thereby the at least some successive ones of the helical convolutions at least in part in another generally axial stack thereof on the one arbor means when the other arbor means is disengaged therefrom.
 7. The method as set forth in claim 6 further comprising the additonal step of stripping the respective one edgewise wound core from the other separation arbor means while it is separated disengaged from the one separation arbor means.
 8. The method as set forth in claim 7 further comprising the further additional step of reengaging the other arbor means with the one arbor means and effecting the displacement of the supporting means from the protracted positions toward retracted positions thereof in response to the reengagement of the arbor means thereby to disassociate the supporting means from the another axial stack of the at least some successive ones of the helical convolutions accumulated on the one arbor means.
 9. The method as set forth in claim 8 further comprising the still further additional step of transferring the another axial stack of the at least some successive ones of the helical covolutions accumulated on the one arbor means to the other arbor means upon the operation of the supporting means toward the retracted positions thereof and continuing the accumulation of others of the successive ones of the helical convolutions in the another axial stack on the other arbor means.
 10. A method of continuously forming edgewise wound cores from a strip of generally thin ferromagnetic material at an operation station with the operation station having a pair of arbor means for engagement with each other and with one of the arbor means being movable toward a displaced position disengaged from the other of the arbor means, and a set of supporting means arranged with the other arbor means for movement between a protracted position extending in part beyond the other arbor means and a retracted position disposed therewithin, the method comprising the steps of:deforming the continuous strip generally edgewise thereof into a plurality of helical convolutions at the operation station; receiving at least some of the helical convolutions about the other arbor means upon the movement of the one arbor means toward its displaced position disengaged from the other arbor means and effecting the movement of the supporting means into their protracted positions in response to the disengagement of the arbor means to accumulate the at least some helical convolutions in a generally axial stack thereof on the supporting means in the protracted positions thereof.
 11. The method as set forth in claim 10 further comprising the additional step of moving the one arbor means into reengagement with the other arbor means and effecting thereby the movement of the supporting means toward the retracted positions thereof.
 12. The method as set forth in claim 11 further comprising the further additional step of disassociating the supporting means from the at least some helical convolutions in the axial stack thereof in response to the moving and effecting step and transferring thereby the at least some helical convolutions in the axial stack thereof from the one arbor means onto the other receiving means engaged without interrupting the progressive deformation of the helical convolutions.
 13. The method as set forth in claim 12 further comprising the still further additional step of continuing the reception of the helical convolutions about the arbor means in engagement with each other and the accumulation of the helical convolutions in the axial stack thereof on the other arbor means and severing a respective one of the helical convolutions upon the progressive deformation thereof at least generally as the axial stack of the helical convolutions accumulated on the other arbor means attains a preselected stack height thereby to form a respective one of the edgewise wound cores.
 14. A method of continuously forming edgewise wound cores from a strip of generally thin ferromagnetic material at at least one operation station with the at least one operation station having a means for receiving the edgewise wound cores, the receiving means including a pair of generally cylindric members each having a circumferental surface, a chamber in at least one of the cylindric members, a set of openings between the chamber and the cylindric surface of the at least one cylindric member, respectively, a set of pins movable in the openings, respectively, a set of cam surfaces on the pins within the chamber, respectively, cam means movable at least in part in the chamber, and an abutment on the other of the cylindric members, the method comprising the steps of:deforming the continuous strip generally edgewise thereof into a plurality of helical convolutions of the strip at the at least one operation station; moving the other cylindric member toward a position displaced from the at least one cylindric member and disengaging thereby the abutment on the other cylindric member from the cam of the at least one cylindric member; resiliently urging the cam toward a position disengaged from the cam surfaces on the pins within the chamber in response to the moving and disengaging step and moving the pins in the openings toward positions extending a part of each of the pins beyond the circumferential surface of the at least one cylindric member; and accumulating generally about the circumferential surface of the at least one cylindric member at least some of the helical convolutions in a generally axial stack thereof deformed during the deforming step and seating the at least some helical convolutions in the axial stack thereof on the pin parts extending beyond the circumferential surface of the at least one cylindric member.
 15. The method as set forth in claim 14 wherein the resiliently urging and moving step includes biasing the pins toward the positions thereof extending the pin parts beyond the circumferential surface of the at least one cylindric member, respectively.
 16. The method as set forth in claim 14 comprising the additional step returning the other cylindric member from the displaced position toward another position at least adjacent the at least one cylindric member and generally in aligned relation therewith and reengaging thereby the abutment on the other cylindric member with the cam of the at least one cylindric member.
 17. The method as set forth in claim 16 comprising the further additional step of driving the cam toward another position effecting the reengagement thereof with the cam surfaces of the pins within the chamber of the at least one cylindric member and moving thereby the pins in the openings toward positions disposing the pin parts within the openings in the at least one cylindric member, respectively.
 18. The method as set forth in claim 17 comprising the still further additional step of unseating the pin parts from the at least some helical convolutions in the axial stack thereof accumulated about the circumferential surface of the at least one cylindric member in response to the driving and moving step, respectively, and transferring the at least some helical convolutions in the axial stack thereof from the at least one cylindric member to transferred positions disposed generally about the circumferential surface of the other cylindric member in its aligned relation with the at least one cylindric member.
 19. The method as set forth in claim 18 comprising the still further additional step of passing additional ones of the helical convolutions deformed during the deforming step about the circumferential surfaces of the at least one cylindric member and the other cylindric member in the aligned relation thereof and accumulating the additional ones of the helical convolutions with the at least some helical convolutions in the axial stack thereof on the other cylindric member to form respective ones of the edgewise wound cores.
 20. A method of continuously forming edgewise wound cores from a strip of generally thin ferromagnetic material at at least one operation station therefor with the at least one operation station having a means for receiving the edgewise wound cores, the receiving means including a pair of separable means adapted for association with each other and separation from each other, and a set of supporting means operable generally in one of the separable means for movement between retracted and protracted positions with respect thereto, respectively, the method comprising the steps of:deforming the continuous strip generally edgewise thereof into a plurality of helical convolutions at the at least one operation station; separating the separable means from each other and effecting thereby the operation of the supporting means toward the protracted position thereof with respect to the one separable means; and extending a part of each supporting means beyond the one separable means in response to the separating and effecting step and receiving at least some of the helical convolutions generally in an axial stack thereof about the one separable means on the supporting means parts when the supporting means are in the protracted positions thereof, respectively.
 21. The method as set forth in claim 20 wherein the separating and effecting step includes resiliently urging the supporting means toward the protracted positions thereof, respectively.
 22. The method as set forth in claim 20 comprising the additional step of associating the separable means with each other and arranging thereby the other of the separable means in position for receiving from the one separable means the at least some helical convolutions in the axial stack thereof.
 23. The method as set forth in claim 22 wherein the associating and arranging step includes effecting the movement of the supporting means from the protracted positions toward the retracted positions thereof and disposing thereby the supporting means parts within the one separable means for disassociating the supporting means parts from the at least some helical convolutions in the axial stack thereof received about the one separable means.
 24. The method as set forth in claim 23 wherein the receiving means further includes means associated with the one separable means for camming in engagement with the supporting means and wherein the effecting and disposing step includes driving the camming means into the engagement thereof with the supporting means in response to the associating and arranging step to effect the movement of the supporting means toward the retracted positions thereof, respectively.
 25. A method of continuously forming edgewise wound cores from a strip of generally thin ferromagnetic material at at least one operation station with the at least one operation station having a means for receiving the edgewise wound cores, the receiving means including a pair of members having at least generally cylindric parts defining at least parts of a generally circumferential surface, a set of pins movable in one of the cylindric members and having a set of cam surfaces thereon, respectively, and a cam movable in the one cylindric member, the method comprising the steps of:deforming the continuous strip generally edgewise thereof into a plurality of helical convolutions at the at least one operation station; displacing the other of the members from the one member; disengaging the cam from the cam surfaces of the pins in response to the displacing step and moving the pins so that a part of each pin extends beyond the at least circumferential surface parts of the one member; and accumulating about the at least circumferential surface part of the one member at least some of the helical convolutions deformed during the deforming step and collecting the at least some helical convolutions generally in an axial stack thereof on the pin parts extending beyond the at least circumferential surface part of the one member, respectively.
 26. The method as set forth in claim 25 comprising the additional step of aligning the members with each other and driving thereby the cam into camming engagement with the cam surfaces on the pins, respectively.
 27. The method as set forth in claim 26 wherein the aligning and driving step includes engaging a part of the other member with the cam to effect the driving thereof upon the alignment of the members.
 28. The method as set forth in claim 26 comprising the further additional step of moving the pins parts generally radially within the at least circumferential surface part of the one member in response to the aligning and driving step, respectively, and transferring thereby the at least some helical convolutions in the axial stack thereof from the one member to the other member generally about the at least circumferential surface part thereof when the members are aligned with each other.
 29. The method as set forth in claim 25 wherein the disengaging and moving step includes resiliently urging the cam toward a position disengaged from the cam surfaces of the pins, respectively.
 30. The method as set forth in claim 25 wherein the disengaging and moving step includes resiliently urging the pins so as to extend the pin parts generally radially beyond the at least circumferential surface part of the one member, respectively. 